Project description:The impairment of the intestinal barrier will lead to the accumulation of fat and harmful substances in the liver, inducing hepatic steatosis or steatohepatitis. Zhang et al. identified NSD2 in the intestine as a novel and essential regulator of hepatic steatosis. NSD2 directly regulates transcriptional activation of ERN1 through the modification of H3 dimethylated on lysine 36 (H3K4me36), thereby activating the ERN1-JNK axis to induce inflammatory response, intestinal barrier impairment, and hepatic steatosis. This functional mechanism of NSD2 provides a potential therapeutic target for this disease.

Project description:The impairment of the intestinal barrier will lead to the accumulation of fat and harmful substances in the liver, inducing hepatic steatosis or steatohepatitis. Zhang et al. identified NSD2 in the intestine as a novel and essential regulator of hepatic steatosis. NSD2 directly regulates transcriptional activation of ERN1 through the modification of H3 dimethylated on lysine 36 (H3K4me36), thereby activating the ERN1-JNK axis to induce inflammatory response, intestinal barrier impairment, and hepatic steatosis. This functional mechanism of NSD2 provides a potential therapeutic target for this disease.

Project description:Metabolic-dysfunction-associated steatotic liver disease (MASLD) has traditionally been studied as a liver-centric condition. However, growing clinical and experimental evidence reveals a strong link between MASLD and cognitive impairment and sensorimotor alterations. The mechanisms underlying this liver-brain axis remain poorly defined, and whether hepatic dysfunction alone is sufficient to drive central nervous system deficits is unclear. Using diet-induced non-obese mouse models of MASLD, we performed comprehensive neurocognitive and behavioral assessments. MASLD was associated with marked alterations in social memory, sensorimotor processing, and hippocampal function, including decreased parvalbumin-positive interneurons, reduced dendritic spine density, and diminished indicators of neurogenesis in the hippocampal dentate gyrus. Then, we selectively modulated liver metabolism through a hepatocyte-targeted siRNA therapy against Cyclin M4 (CNNM4), a magnesium transporter dysregulated in MASLD, employing GalNAc-siRNA technology for targeted delivery. Notably, liver-specific intervention with siRNA-CNNM4 reversed features of impaired social memory and sensorimotor processing through recovery of hippocampal synaptogenesis and mitochondrial function pathways, alongside activation of neurogenesis-associated transcriptional programs. Our findings demonstrate that liver pathology is sufficient to drive neurobehavioral and hippocampal dysfunction in MASLD. Importantly, hepatic-specific intervention restores brain function, strongly supporting the existence of a causal and therapeutically targetable liver-brain axis. These results open new avenues for treating MASLD-associated neurological complications through liver-directed therapies.

Project description:DNA demethylation is regulated by the TET family proteins, whose enzymatic activity requires 2-oxoglutarate (2-OG) and iron that both are elevated in MASLD. We aimed to investigate liver TET1 in MASLD progression. Depleting TET1 substantially alleviated MASLD progression. Whole body Knockout of TET1 (TKO) slightly improved diet induced obesity and glucose homeostasis. Intriguingly, hepatic cholesterols, triglycerides, were significantly decreased upon TET1 depletion. Moreover, targeting TET1 with a small molecule inhibitor significantly suppressed MASLD progression. Liver TET1 plays a deleterious role in MASLD, suggesting the potential of targeting TET1 in hepatocytes to suppress MASLD.

Project description:NSD2 aggravates metabolic dysfunction-associated steatotic liver disease progression by suppressing TFEB-mediated autophagy-lysosomal pathway

Project description:Analyze human biopsies for the investigation of metabolic dysfunction-associated steatotic liver disease (MASLD). We also analyzed plasma samples for biomarker discovery. And analyzed the role of the impact of the adipose tissue on plasma proteins in relation to MASLD

Project description:This SuperSeries is composed of the following subset Series: GSE29146: NSD2 links dimethylation of histone H3 at lysine 36 to oncogenic programming [ChIP] GSE29147: NSD2 links dimethylation of histone H3 at lysine 36 to oncogenic programming [RNAi] GSE29148: NSD2 links dimethylation of histone H3 at lysine 36 to oncogenic programming [TKO] GSE29150: NSD2 links dimethylation of histone H3 at lysine 36 to oncogenic programming [Transduction] Refer to individual Series

Project description:NSD2 (also named MMSET and WHSC1) is a histone lysine methyltransferase that is implicated in diverse diseases and commonly overexpressed in multiple myeloma due to a recurrent t(4;14) chromosomal translocation. However, the precise catalytic activity of NSD2 is obscure, preventing progress in understanding how this enzyme influences chromatin biology and myeloma pathogenesis. Here we show that dimethylation of histone H3 at lysine 36 (H3K36me2) is the principal chromatin-regulatory activity of NSD2. Catalysis of H3K36me2 by NSD2 is sufficient for gene activation. In t(4;14)-positive myeloma cells, the normal genome-wide and gene-specific distribution of H3K36me2 is obliterated, creating a chromatin landscape that selects for a transcription profile favorable for myelomagenesis. Catalytically active NSD2 confers xenograft tumor formation and invasion capacity upon t(4;14)-negative cells and NSD2 promotes oncogenic transformation of primary cells in an H3K36me2-dependent manner. Together our findings establish H3K36me2 as the primary product generated by NSD2, and demonstrate that genomic disorganization of this canonical chromatin mark initiates oncogenic programming. Genome-wide expression profiling of KMS11 cells stably transduced with control vector in comparison to two independent shRNAs against NSD2. Each cell line is tested in duplicate.

Project description:NSD2 (also named MMSET and WHSC1) is a histone lysine methyltransferase that is implicated in diverse diseases and commonly overexpressed in multiple myeloma due to a recurrent t(4;14) chromosomal translocation. However, the precise catalytic activity of NSD2 is obscure, preventing progress in understanding how this enzyme influences chromatin biology and myeloma pathogenesis. Here we show that dimethylation of histone H3 at lysine 36 (H3K36me2) is the principal chromatin-regulatory activity of NSD2. Catalysis of H3K36me2 by NSD2 is sufficient for gene activation. In t(4;14)-positive myeloma cells, the normal genome-wide and gene-specific distribution of H3K36me2 is obliterated, creating a chromatin landscape that selects for a transcription profile favorable for myelomagenesis. Catalytically active NSD2 confers xenograft tumor formation and invasion capacity upon t(4;14)-negative cells and NSD2 promotes oncogenic transformation of primary cells in an H3K36me2-dependent manner. Together our findings establish H3K36me2 as the primary product generated by NSD2, and demonstrate that genomic disorganization of this canonical chromatin mark initiates oncogenic programming. Genome-wide expression profiling of p19ARF-/- mouse embryonic fibroblasts stably transduced with control vector or wild-type NSD2. Each cell line is tested in triplicate.

Project description:Metabolic dysfunction-associated steatotic liver disease (MASLD) and metabolic dysfunction-associated steatohepatitis (MASH) are two common liver disorders characterized by abnormal lipid accumulation. Our study found reduced levels of GTPase-activating protein-binding protein1（G3BP1）in patients with MASLD and MASH, suggesting its involvement in these liver disorders. Hepatocyte-specific G3BP1 knockout (G3BP1 HKO) mice had more severe MASLD and MASH than their corresponding controls. Intriguingly, the G3BP1 HKO MASLD model mice exhibit dysregulated autophagy, and biochemical analyses demonstrated that G3BP1 promotes autophagosome-lysosome fusion through direct interactions with the SNARE proteins STX17 and VAMP8. We also show that hepatic knockout of G3BP1 promotes de novo lipogenesis, and ultimately found that G3BP1 is required for the nuclear translocation of the well-known liver-lipid-regulating transcription factor TFE3. Taken together, our results suggest that G3BP1 should be investigated as a potential target for developing medical interventions to treat MASLD and MASH.